DE3610248A1 - METHOD FOR PRODUCING REMOTE ALLOYS - Google Patents

Description

The invention relates to alloys with a content of metallic iron for use in the manufacture of iron and steel and a method of manufacture such alloys.

25 In the manufacture of iron and steel, it is common to add certain additives to the furnace, such as various metal-containing products in the form of alloys, such as ferrosilicon, ferronickel, ferrochrome, ferro-manganese and Like. To feed. These ferro alloys normally contain

30 times a considerable amount of carbon. According to the invention metallized iron, the alloying element in the oxide form, and carbon become a compact or briquette shaped, then together with an additional carbonaceous material such as coke,

35, if necessary, placed in a shaft furnace and reduced to form a molten ferro-alloy product which is valuable in foundry technology and

other iron and steel manufacturing uses.

The composition of the briquette to be introduced into the shaft furnace preferably has metalized iron fines as a basic component. In the previously known briquettes, fine iron oxide parts or -Grus used. Due to the presence of metallized fines, the energy requirement for the inventive Procedure decreased. Since the iron fines are in a metallized state, the energy normally required to reduce iron oxide to iron in the process of the invention not mandatory. Since the iron in the briquette does not need to be reduced before melting, the energy requirement is less.

LJ The patents closest to the subject of the application include US Pat. Nos. 4,179,283, 4,395,284 and 4,369,062. The first-mentioned US patent describes only the briquetting of metal oxides and no directly reduced iron is used in the briquette -Charge used. Two carbon sources, a carbon with a high reactivity and a carbon with a low reactivity, are used.

In U.S. Patent 4,395,284, iron and a binder are optional components rather than essential components specified. Porous compacts are made for use as a feedstock for one Electric furnace, the material having a low apparent density and high internal porosity. In this it is stated that up to about 15% by weight of silica can be iron particles, they will however, referred to as mill scale, which is generally in the oxide form.

In U.S. Patent 4,369,062, the manufacture of a briquette from up to 41% recovered materials is such as e.g. iron fines and roller igniters. One Investigation has shown that there is not enough carbon in these briquettes to remove the mill scale to reduce. In addition, an additional source of energy is required, which is heat during melting supplies.

The present invention differs from each of these patents in that they are established Briquettes the desired alloy oxide, carbon and iron, which is over 60% metallized, and a binder, such as sodium silicate or a mixture of calcium hydroxide and molasses.

Λ- The main aim of the present invention is to provide a method ^; Ren for more economical production of a ferroalloy than was previously possible to make available for various steel production and foundry processes.

85 to 99 parts of a mixture of a finely divided material, consisting essentially of 10 to 90% metallized ^ ices, 7 to 65% alloy oxide and 5 to 26% carbon, are mixed with 1 to 15 parts of binder mixed and pressed to make a briquette. The optimal briquette contains 92% finely divided material and 8% binder. The briquette is fed into a shaft furnace along with additional carbonaceous Material that is burned to heat and reduce the alloy oxide to the metallized one Mold, for melting the iron and the alloying element and for forming a ferro-alloy melt in the oven.

In the process according to the invention, an iron-containing briquette is used as the feed material consisting essentially of about 10 to 90% metallized iron, about 7 to about 65% alloy in the metal oxide form and consists of about 5 to about 26 percent carbon. The iron in the composition can be in the form of chips, Splinters or in the form of metallized iron fines, but the latter are preferred. Metallized Iron fines are preferably produced by direct reduction of iron oxide and are at least 60%, but usually more than 80% metallized.

The preferred binders are 3 parts lime and 5 parts Molasses. The lime for the binder is in the form of hydrated lime, which is calcium hydroxide acts, before.

All of these components should be in one-part form, preferably with a particle size of less than 3 millimeters.

Silica, manganese oxide, chromite, molybdenum oxide, nickel oxide, cobalt oxide, vanadium oxide, or any other desirable one Alloy oxide is in the form of fines or in granulated form. Such oxides are here to facilitate identification in equations designated by the formula "MO".

Ji

The metallized iron fines within the briquette melt with the formation of discrete iron droplets, which are saturated in carbon. The carbon is preferably a component of a solid fuel, such as coal or coke, alternatively pitch or tar can be used. The briquette should be about that stoichiometric requirements in addition to contain additional carbon to make a proportion available to have, which is used as fuel for the delivery of the reaction

heat for the reduction and for supplying the energy required to heat and melt the reduced Iron and silicon up to the tapping temperature (about 1500 ° C or 2700 ° F) is used. The function of carbon in the briquette is the following:

1) It supplies the energy required for the heat of reaction to reduce the alloy metal oxide particles in accordance with the reaction equation: + £ M _(s) + CO

_(s)

2) it provides the energy required to dissolve the carbon in the molten iron according to the reaction equation:
_r heat _{v r}
^C (s) £ 7

3) it provides the necessary to satisfy the enthalpy requirements when heating the iron and metallized oxide particles after the reduction) up to the tapping temperature required energy; and

4) it provides what is necessary to dissolve the reduced metal particles in the molten iron

^w energy according to the reaction equation:

The particle size of all components is preferably less than 25 millimeters, and it is most advantageous however, if the particle size of all components before briquetting is less than 15 millimeters.

A particularly advantageous area of the components in the briquette is 20 to 70% metallized iron, 15 to 60% alloy oxide and 9 to 23% carbon. The optimal composition is 40 to 55% metallized iron, 20 to 40% alloy oxide and 13 up to 21% carbon.

The above mixture can by hot briquetting at a temperature of at least 600 C and at a Pressure of at least. 70 bar (1000 psi) to one

hot briquette containing iron.

The preferred binder is a mixture of calcium hydroxide and molasses in approximately equal proportions with an optimal composition of 3 parts lime to 5 parts molasses. However, you can use one at a time Amount of 30 to 70% of the binder is present. Alternative binders are sodium silicate, pitch and Tars, other organic or chemical binders and cements.

When carrying out the method according to the invention the ferro-alloy briquette is melted in a shaft furnace device, such as a cupola or other melting furnace. A significant proportion of the Alloy oxide in the briquette is reduced during the melting process and the metallic alloy element becomes available as an alloying element for the molten product. From this it can be seen that the ferro- Alloy briquettes can replace the more expensive ferro-silicon or another ferro-alloy.

Losses occur in a cupola furnace, which is a smelting furnace rather than a reduction furnace in melt productivity when the reduction of both alloy oxide and iron oxide in must be carried out in the oven. If only the alloy oxide needs to be reduced, that is, if that Iron oxide has already been reduced to metallized iron, the losses in smelting productivity are minimal.

The oxygen for the combustion in the cupola is obtained from preheated air, possibly with oxygen enrichment, delivered. The cupola can be a conventional coke cupola or a coke-free cupola or deal with any desired furnace,

the one made by oxy-fuel burners, enriched with oxygen Air / natural gas torch, plasma torch or electrodes such as carbon arc electrodes in one

electric arc furnace that can be fired. 5

The imported briquette consists essentially of metallized Iron fines, a finely divided or granulated alloy in the oxide form, a carbon source, such as coke breeze or coal fines, and a binder, such as a mixture of calcium hydroxide and molasses. After the mixture has been pressed into a briquette, the briquette can be used at a be dried or cured at a low temperature, for example at 150 to 2OO ° C (about 300 to 400 F), to remove any moisture and improve green strength.

Splinters, particles or chips made of stainless steel or a steel alloy or non-iron oxides, such as ilmenite, chromite, titanium dioxide concentrates, nickel laterites or oxides, and even steel alloy mill scale be included.

Sufficient additional carbon in the form of a solid carbonaceous material such as coke is added to the Melting furnace fed in such an amount that it meets the enthalpy and heat melting requirements to the solid iron, the solid iron alloy and the slag formers that are introduced into the melter have been melted and made available carbon to such an extent that that it is partially oxidized to form a non-oxidizing atmosphere in the melting zone of the melting device, to protect the iron and any reduced alloy particles from oxidation.

/ y 1 The following tables compare the chemical analyzes of various ferrosilicon compositions with equivalent ferrosilicon dioxide briquettes as used according to the invention. 5

Table I. Ferrosilicon Analysis

Ferrosil ic ium- FeSi 1 FeSi 5 FeSi 10 FeSi 25 FeSi 50 FeSi 75 designation

Fe 98 _r 5% 94.5% 89.5% 74.5% 49.5% 24.5%

Si 1.0 5.0 10.0 25.0 50.0 75.0

C 0.5 0.5 0.5 0.5 0.5 0.5

Table II

Ferrosilica Briquette Composition 20

Ferrosilicon

Equivalent FeSi 1 FeSi 5 FeSi 10 FeSi 25 FeSi 50 FeSi 75

Metallized

Iron fine particles 96.6% 86.7% 75.9% 51.6% 26.2% 10.5%

SiO ₂ 0.5 7.8 15.7 33.5 52.1 63.6

C 2.9 5.5 8.4 14.9 21.7 25.9

. Table III Ferrosilica Briquette Analysis

FeSi 1 FeSi 5 FeSi 10 FeSi 25 FeSi 50 FeSi 75

43.7% 22.2% 8.9%

4.9 2.5 1.0

15.7 22.1 26.0

Fe 81.9% 73.5% 64.4 FeO 9.3 8.3 7.3 C. 4.3 6.8 9.5 SiO ₂ 1.9 9.1 16.8 CaO 0.9 0.8 0.7 Other 1.6 1.5 1.3

"* ^{n Λ} ° ⁿ - " ^c ° 34.3 52.5 63.8

0.5 0.3 0.1

0.9 0.4 0.2

The term "metallized" used here is not to be understood as meaning a state coated with a metal, but a state that is almost completely metallic, that is, always more than 60% metal and usually more than 80% metal in the material is reduced. Such a metallized one Iron is available in many forms including pellet form as a feedstock for steelmaking furnaces, such as an electric arc furnace, are well suited.

Alternative binders of the matrix type, such as coal tar pitch, or of the film type, such as sodium silicate, or chemical-type such as hydrated lime and carbon dioxide are also suitable binders in accordance with the invention.

The feed for the cupola can be a mixture of briquettes, hot briquetted iron, non-alloy carbon steel waste, Alloy steel waste can be recovered cast iron and coke.

Flux additives / such as limestone, quick lime, dolomite lime, spar and the like, can be used to form a suitable Slag can be used either for desulfurization, for dephosphorization or both or just around To transfer flux impurities from the melt into the slag.

The molten ferro-alloy product can be granulated or cast into ingots or small slabs.

From the above description it can be seen that with the method of the invention for the production of molten Ferro alloys the above object of the invention is achieved. It is clear that the invention is in no way limited to the embodiments described above, but that these in many ways Aspects can be changed and modified without thereby departing from the scope of the present invention will.

Claims (8)

Claims 1. A process for the manufacture of a ferro-alloy, characterized in that it comprises: dais forms of compacts which essentially consist from a mixture of metallized iron, a stoichiometric one Excess of solid carbonaceous material and an oxide of a metal selected from Group silicon, nickel, manganese, titanium, vanadium, chromium, molybdenum and cobalt, the introduction of these compacts and slag formers into a melting furnace, burning the solid carbonaceous material to reduce the oxides in the compacts, the components to melt and form a high alloy melt. 2. The method according to claim 1, characterized in that it further comprises the addition of carbon, metallic Aluminum, metallic magnesium or any combination thereof to the compact prior to introduction same in the oven. 3. The method according to claim 1 and / or 2, characterized in that that it also includes the introduction of an additional solid carbonaceous material in the furnace to provide additional heat and reactive carbon. 4. The method according to at least one of claims 1 to 3, characterized in that it also comprises the Introduction of solid iron, an iron alloy, hot briquette Iron, from carbon steel scrap, alloy steel scrap, reclaimed cast iron, or any Mix it in the furnace. 5. The method according to at least one of claims 1 to 4, characterized in that it further comprises the introduction of oxygen into the furnace in order to start the combustion to support.
5 6. The method according to at least one of claims 1 to 5, characterized in that the oxygen is in the form of preheated air. 7. The method according to at least one of claims 1 to 6, characterized in that it also comprises the supply of heat to the furnace by means of oxy-fuel burners, oxygen-enriched air / natural gas burners, plasma burners or electrodes. 8. The method according to at least one of claims 1 to 7, characterized in that it also includes the Use of a compact which contains at least one component which is selected from the group of Splinters, fine parts and shavings made from a stainless steel alloy, ilmenite, chromite, titanium dioxide concentrates, Nickel laterites, nickel oxides and steel alloy mill scale.